We post all of our manuscripts on preprint servers such as the bioRxiv to enable faster and broader dissemination of our research. We also share custom software outputs on GitHub, our plasmids are on Addgene, and are glad to provide copies of our preprints, data, and protocols for all of our work upon request.

*Denotes equal contribution ^‡ Denotes corresponding author

.

2024

100. Huzar, J., Coreas, R., Landry, M.P., Tikhomirov^‡ AI-based Prediction of Protein Corona Composition on DNA Nanostructures. bioRxiv (2024)

99. Ashkarran, A.A., Gharibi, H, Sadeghi, S.A., Modaresi, S.M., Wang, Q., Lin, Lin, T., Yerima, G., Tamadon, A., Sayadi, M., Jafari, M., Lin, Z., Ritz, D., Kakhniashvili, D., Guha, A., Mofrad, M., R., Sun, L., Landry, M.P., Saei, A.A., Mahmoudi, M.^‡ Small molecule modulation of protein corona for deep plasma proteome profiling. Nature Communications (2024) – PDF

98. Lin, T., Landry, M.P.^‡Quantifying Data Distortion in Bar Graphs in Biological Research. bioRxiv (2024)

97. Nishitani, S., Liang, Z., Smith, D., Landry, M.P.^‡High-purity single-molecule modification of carbon nanotubes by stochastic distribution of DNA. chemRxiv (2024)

96. Nishitani, S., Ao, K., Jalil, A., Arias, T., Moudi, A., Chen, F., Biyani, A., Nuppirala, P., Landry, M.P.^‡ Redox dye-mediated fluorescence energy transfer of carbon nanotube based nanosensors. chemRxiv (2024)

95. Klinger, M.E., Miller, R., Wilbrecht, L., Landry, M.P.^‡ Optical Fibers Functionalized with Single-Walled Carbon Nanotubes for Flexible Fluorescent Catecholamine Detection. bioRxiv (2024)

94. Mun, J.*, Navarro, N.*, Jeong, S.*, Ouassil, N., Leem, E., Beyene, A.G., Landry, M.P.^‡ Near Infrared Nanosensors Enable Optical Imaging of Oxytocin with Selectivity over Vasopressin in Acute Mouse Brain Slices. PNAS (2024) – PDF

93. Safaee, M.M.*, Nishitani, S.*, McFarlane, I.R., Yang, S.J, Sun, E., Medina, S.M, Landry, M.P.^‡Dual Infrared 2-Photon Microscopy Achieves Minimal Background Deep Tissue Imaging in Brain and Plant Tissues. Advanced Functional Materials (2024) – PDF

92. Ledesma, F., Nishitani, S., Cunningham, F.J., Hubbard, J.D., Yim, D., Lui, A., Chio, L., Murali, A., Landry, M.P.^‡ Covalent Attachment of Horseradish Peroxidase to Single-Walled Carbon Nanotubes for Hydrogen Peroxide Detection. Advanced Functional Materials (2024) – PDF

91. Squire, H., Kim, M., Wong, C., Seng, A., Lee, A., Goh, N., Wang, J., Landry, M.P.^‡ Cellulose Nanocrystals Protect Plants from Pathogen Infection. ACS Applied Nanomaterials (2024) – PDF

90. Gharibi, H. Ashkarran, A., Jafari, M., Voke, E., Landry, M.P. Saei, A., Mahmoudi, M.^‡ A uniform data processing pipeline enables harmonized nanoparticle protein corona analysis across proteomics core facilities. Nature Communications (2024) – PDF

89. Kelich, P., Adams, J., Jeong, S., Navarro, N., Landry, M.P., Vuković, L.^‡ Predicting Serotonin Detection with DNA-Carbon Nanotube Sensors Across Multiple Spectral Wavelengths. Journal of Chemical Information and Modeling (2024) – PDF

2023

88. Rosenberg, D., Cunningham, F., Hubbard, J., Goh, N., Wang, J., Nishitani, S., Hayman, E., Hura, G,. Landry, M.P. , Pinals, R.^‡ Mapping the Morphology of DNA on Carbon Nanotubes in Solution using X-ray Scattering Interferometry. JACS, (2023) – PDF

87. Nishitani, S., Tran, T., Puglise, A., Yang, S., Landry, M.P.^‡ Engineered Glucose Oxidase-Carbon Nanotube Conjugates for Tissue-Translatable Glucose Nanosensors. *Featured Frontpiece Cover* Angewandte Chemie (2023) – PDF

86. Wang, J.W., Squire, H.J., Goh, N.S., Ni, H.N., Lien, E.S., Wong, C., Gonzales-Grandio, E., Landry, M.P.^‡ Delivered complementation in planta (DCIP) enables measurement of peptide-mediated protein delivery efficiency in plants. Nature Communications Biology (2023) – PDF

85. Hajipour, M.J, Safavi-Sohi, R., Sharifi, S., Mahmoud, N., Akbar, A., Voke, E., Serpooshan, V., Ramezankhani, M., Milani, A.S., Landry, M.P.^‡ Mahmoudi, M.^‡An overview of nanoparticle protein corona literature. *Inside Journal Cover* Small (2023) – PDF

84. Yang, S.J., O’Donnell J.T., Giordani, F., Beyene, A., Piekarski, D., Schaffer, D.^‡, Landry, M.P.^‡ Synaptic scale dopamine disruption in Huntington’s Disease model mice imaged with near infrared catecholamine nanosensors. bioRxiv (2023) – PDF

83. Mahmoudi, M.^‡, Landry, M.P., Moore, A., Coreas, R.^‡ The protein corona from nanomedicine to environmental science. Nature Reviews Materials (2023) *Journal Cover* – PDF

82. Squire, H.J., Tomatz, S., Voke, E., Landry, M.P.^‡ The emerging role of nanotechnology in plant genetic engineering. Nature Reviews Bioengineering (2023) *Journal Cover* – PDF

81. Sorooshyari, S., Ouassil, N., Yang, S., Landry, M.P.^‡ Identifying Neural Signatures of Dopamine Signaling with Machine Learning. ACS Chemical Neuroscience (2023) *Journal Cover* – PDF

2022

80. Ashkarran, A.A., Gharibi, H., Voke, E., Landry, M.P., Saei, A.A.^‡, Mahmoudi, M.^‡ Measurements of heterogeneity in proteomics analysis of nanoparticle protein corona across core facilities. Nature Communications (2022) – PDF

79. Sharifi, S., Mahmoud, N., Voke, E., Landry, M.P., Mahmoudi, M.^‡ Importance of Standardizing Analytical Characterization Methodology for Improved Reliability of the Nanomedicine Literature. Nano-Micro Letters (2022) – PDF

78. Munos, A., Theusch, E., Kuang, Y.L., Nalula, G., Peaslee, C., Dorlhiac, G., Landry, M.P. Streets, A., Krauss, R.M., Iribarren, C., Mattis, A.N., Medina, M.W.^‡ Undifferentiated Induced Pluripotent Stem Cells as a Genetic Model for Nonalcoholic Fatty Liver Disease. Cellular and Molecular Gastroenterology and Hepatology (2022) – PDF

77. Zhang, H.* Goh, N.S.*, Wang, J., Demirer, G.S., Butrus, S., Park, S-J, Landry, M.P.^‡ Nanoparticle Cellular Internalization is Not Required for RNA Delivery to Mature Plant Leaves. Nature Nanotechnology (2022) – PDF

76. Dorlhiac, G.F., Streets, A., , Landry, M.P.^‡ Leveraging isotopologues as a general strategy to image neurotransmitters with vibrational microscopy. arXiv (2022) – PDF

75. Zhang, X., Dorlhiac, G., Landry, M.P., Streets, A.^‡ Phototoxic effects of nonlinear optical microscopy on cell cycle, oxidative states, and gene expression. Scientific Reports (2022) – PDF

74. Zahir, A., Serag, M.F., Demirer, G.D., Torre, B., di Fabrizio, E., Landry, M.P., Habuchi, S.^‡, Mahfouz, M.^‡ DNA-Carbon Nanotube Binding Mode Determines the Efficiency of Carbon Nanotube-Mediated DNA Delivery to Intact Plants. ACS Applied Nano Materials (2022) – PDF

73. Ouassil, N., Pinals, R.L., O’Donnell, J.T., Wang, J., Landry, M.P.^‡ Supervised Learning Model Predicts Protein Adsorption to Nanotubes. Science Advances (2022) – PDF

2021

72. Jackson, C.T., Wang, J.W., Gonzalez-Grandio, E., Goh, N.S., Mun, J., Krishnan, S., Landry, M.P.^‡ Polymer-Conjugated Carbon Nanotubes for Biomolecule Loading. ACS Nano (2021) – PDF

71. Kelich, P.*, Jeong, S.*, Navarro, N.*, Adams, J., Sun, X., Zhao, H., Landry, M.P.^‡ Vukovic, L.^‡Machine learning enables discovery of DNA-carbon nanotube sensors for serotonin. ACS Nano (2021) – PDF

70. Gonzalez-Grandio, E., Demirer, G.S., Jackson, C., Yang, D., Landry, M.P.^‡ Carbon nanotube biocompatibility in plants is determined by their surface chemistry. Journal of Nanobiotechnology (2021) – PDF

69. Ledesma, F., Ozcan, B., Sun, X., Medina, S.M., Landry, M.P.^‡ Nanomaterial Strategies for Delivery of Therapeutic Cargoes. Advanced Functional Materials (2021) – PDF

68. O’Donnell, J.T., Mun, J., Delevich, K.^‡, Landry, M.P.^‡ Synthetic nanosensors for imaging neuromodulators. Journal of Neuroscience Methods (2021) – PDF

67. Voke, E., Pinals, R.L, Goh, N. S., Landry, M.P.^‡ In Planta Nanosensors: Understanding Bio-Corona Formation for Functional Design. ACS Sensors (2021) – PDF

66. Gonzalez-Grandio, E., Demirer, G.S., Ma, W., Brady, S.M., Landry, M.P.^‡ A ratiometric dual color luciferase reporter for fast characterization of transcriptional regulatory elements. ACS Synthetic Biology (2021) – Addgene plasmids – PDF

65. Wang, J.W., Cunningham, F.J., Goh, N. S., Boozarpour, N.N., Pham, M., Landry, M.P.^‡ Nanoparticles for protein delivery in planta. Current Opinion in Plant Biology (2021). 60(102052). – PDF

64. Zhang, H., Cao, Y., Xu, D., Goh, N.S., Demirer, G.S., Chen, Y., Landry, M.P.^‡, Yang, P.^‡ Gold nanocluster mediated delivery of siRNA to intact plant cells for efficient gene knockdown. Nano Letters (2021). – PDF

63. Jackson, C., Jeong, S., Dorlhiac, G.F., Landry, M.P.^‡ Advances in engineering near-infrared luminescent materials. iScience (2021). – PDF

62. Pinals, R. L., Ledesma, F., Yang, D., Navarro, N., Jeong S., Pak, J.E., Kuo, L., Chuang, Y.C., Cheng Y.W., Sun, H.Y., Landry, M.P.^‡ Rapid SARS-CoV-2 Detection by Carbon Nanotube-Based Near-Infrared Nanosensors. Nano Letters (2021). – PDF

61. Jeong, S., Grandio, E.G., Navarro, N., Pinals, R., Ledesma, F., Yang, D., Landry, M.P.^‡ Extraction of Viral Nucleic Acids with Carbon Nanotubes Increases SARS-CoV-2 RT-qPCR Detection Sensitivity. ACS Nano (2021). – PDF

60. Yang, D., Yang, S., Del Bonis O’Donnell, J.T., Landry, M.P.^‡ Near-infrared catecholamine nanosensors for high spatiotemporal dopamine imaging. Nature Protocols (2021). – PDF

59. Demirer, G.S.^‡, Silva, T.N., Jackson, C.T., Thomas, J.B., Ehrhardt, D., Rhee, S.Y.^‡, Mortimer, J.C.^‡, Landry, M.P.^‡ Nanotechnology to advance CRISPR/Cas genetic engineering of plants. Nature Nanotechnology (2021). – PDF

58. Demirer, G.S.^‡, Landry, M.P.^‡ Efficient Transient Gene Knock-down in Tobacco Plants Using Carbon Nanocarriers. Bio Protocol (2021). 11(1) – PDF

.

2020

57. Lui, A.*, Hubbard, J.D.*, Landry, M.P.^‡ Multiscale and multidisciplinary approach to understanding nanoparticle transport in plants. Current Opinion in Chemical Engineering (2020). DOI: 10.1016/j.coche.2020.100659 – PDF

56. Pinals, R.L., Yang, D., Rosenberg, D.J., Chaudhary, T., Crothers, A.R., Iavarone, A.T., Hammel, M., Landry, M.P.^‡ Quantitative Protein Corona Composition and Dynamics on Carbon Nanotubes in Biological Environments. Angewandte Chemie (2020). DOI: 10.1002/anie.202008175 – PDF

55. Yang, D., Yang, S., Del Bonis O’Donnell, J.T., Pinals, R., Landry, M.P.^‡ Mitigation of carbon nanotube neurosensor induced transcriptomic and morphological changes in mouse microglia with surface passivation. ACS Nano (2020). DOI: 10.1101/2020.06.30.181420v1 – PDF

54. Hofmann, T.^‡, Lowry, G.V.^‡, Ghoshal, S., Tufenkji, N., Brambilla, D., Dutcher, J.R., Gilbertson, L.M., Giraldo, J. P., Kinsella, J. M., Landry, M.P., Lovell, W., Naccache, R., Paret, M., Pedersen, J. A., Unrine, J., M., White, J.C., Wilkinson, K.J. Technology readiness and overcoming barriers to sustainably implement nanotechnology-enabled plant agriculture. Nature Food (2020). DOI: 10.1038/s43016-020-0110-1 – PDF

53. Pinals, R.L., Chio, L., Ledesma, F., Landry, M.P.^‡ Engineering at the nano-bio interface: harnessing the protein corona towards nanoparticle design and function. Analyst (2020), DOI: 10.1039/D0AN00633E – PDF

52. Zhang, H.^‡, Liu, X., Zhang, C., Su, J., Lu, X., Shi, J., Wang, L., Landry, M.P., Zhu, Y., Lv, M., Mi, X. Ultrasensitive Fluorescent Microarray Platform for Nucleic Acid Test. Sensors and Actuators B (2020). DOI: 10.1016/j.snb.2020.128538 – PDF

51. Demirer, G.S., Zhang, H., Goh, N., Pinals, R.L., Chang, R., Landry, M.P.^‡ Carbon nanocarriers deliver siRNA to intact plant cells for efficient gene knockdown. Science Advances (2020) – PDF

50. Zhang, H., Zhang, H., Demirer, G.S., Gonzales-Grandio, E., Fan, C., Landry, M.P.^‡ Engineering DNA nanostructures for siRNA delivery in plants. Nature Protocols (2020). DOI: 10.1038/s41596-020-0370-0 – PDF

- Selected as the Featured Nature Protocol of the week

49. Jeong, S.*, Pinals, R.L.*, Sharmadhikari, B., Song, H., Kalluri, A., Debnath, D., Wu, Q., Ham, M.H., Patra, P.^‡, Landry, M.P.^‡. Graphene quantum dot oxidation governs noncovalent biopolymer adsorption. Scientific Reports (2020) – PDF

48. Heller, D.^‡, Jena, P., Pasquali, M. Kostarelos, K.,… Landry, M.P., Wenseleers, W., Yudaska, M. Banning carbon nanotubes would be scientifically unjustified and damaging to innovation. Nature Nanotechnology (2020). DOI: 10.1038/s41565-020-0656-y – PDF

47. Cunningham, F.J., Demirer, G.S., Goh, N.S., Zhang, H., Landry, M.P.^‡. Nanobiolistics: An Emerging Genetic Transformation Approach. Biolistic DNA Delivery in Plants (2020) pp 141-159 – PDF

46. Alizadehmojarad, A.A., Zhou, X., Beyene, A.G., Chacon, K., Sung, Y., Landry, M.P.^‡, Vuković, L.^‡. Binding affinity and conformational preferences influence kinetic stability of short oligonucleotides on carbon nanotubes. Advanced Materials Interfaces (2020) – PDF

45. Chio, L., Pinals, R.L., Murali, A., Goh, N.S., Landry, M.P.^‡ Covalent Surface Modification Effects on Single-Walled Carbon Nanotubes for Targeted Sensing and Optical Imaging. Advanced Functional Materials (2020) – PDF

44. Pinals, R.L.*, Yang, D.*, Lui, A., Cao, W., Landry, M.P.^‡ Corona exchange dynamics on carbon nanotubes by multiplexed fluorescence monitoring. JACS (2020) – PDF

.

2019

43. Demirer, G.S., Zhang, H., Goh, N.S, Gonzalez-Grandio, E., Landry, M.P.^‡ Carbon nanotube-mediated DNA delivery without transgene integration in intact plants. Nature Protocols (2019) – PDF

42. Lui, A., Wang, J., Chio, L., Landry, M.P.^‡ Synthetic probe development for measuring single or few-cell activity. Methods in Enzymology (2019) – PDF

41. Landry, M.P.^‡and Mitter, N.^‡ How nanocarriers delivering cargos in plants can change the GMO landscape. Nature Nanotechnology (2019) 14; pp. 512–514 – PDF

40. Beyene, A.G., Delevich, K., Del Bonis-O’Donnell, J.T., Piekarski, D.J., Lin, W.C., Thomas, A.W., Yang, S.J., Kosillo, P., Yang, D., Wilbrecht, L.^‡, Landry, M.P.^‡Imaging Striatal Dopamine Release Using a Non-Genetically Encoded Near-Infrared Fluorescent Catecholamine Nanosensor. Science Advances (2019). 5; 1-11- PDF GitHub Code

- See press coverage in Nature: Microscopic sensors reveal the brain’s chemical chatter
- C&EN video press coverage: Nanosensors shine a light on brain chemistry

39. Zhang,* H., Demirer, G.S.*, Zhang, H.*, Ye, T., Goh, N., Aditham, A.J., Cunningham, F.J., Fan, C., Landry, M.P.^‡ DNA Nanostructures Coordinate Gene Silencing in Mature Plants. PNAS (2019). DOI: 10.1073/pnas.1818290116 – PDF

- See press coverage by the UC Berkeley College of Chemistry

38. Demirer, G.S., Zhang, H., Matos, J., Goh, N., Cunningham, F.J., Sung, Y., Chang, R., Aditham, A.J., Chio, L., Cho, M.J., Staskawicz, B., Landry, M.P.^‡ High Aspect Ratio Nanomaterials Enable Delivery of Functional Genetic Material Without Transgenic DNA Integration in Mature Plants. Nature Nanotechnology (2019). DOI: 10.1038/s41565-019-0382-5 – PDF

- C&EN news article: Carbon nanotubes deliver DNA into plant cells
- NPR interview on All Things Considered
- Berkeley news article: With nanotubes, genetic engineering in plants is easy-peasy
- Featured on NPR’s Changing the World One Invention at a Time series
- Innovative Genomics Institute news article: DNA Takes a Ride on a Nanotube: Next Stop, Genome-Edited Crops
- Popular Mechanics: An Advance in Bioengineering Could Pave the Way for Tomorrow’s superplants
- Press coverage in Yahoo! News, Phys.org, nanowerk, UK Times, EurekAlert, PhysicsWorld, and seedquest

37. Chio, L., Del Bonis-O’Donnell, J.T., Kline, M., Kim, J.H., McFarlane, I.R., Zuckermann, R.N., Landry, M.P.^‡Electrostatic-assemblies of single-walled carbon nanotubes and sequence-tunable peptoid polymers detect a lectin protein and its target sugars. Nano Letters (2019) 19 (11); pp. 7563-7572. DOI: 10.1021/acs.nanolett.8b04955 – PDF

- This article selected as the Nano Letters cover

36. Wang, J.W., Grandio, E.G., Newkirk, G.M., Demirer, G.S., Butrus, S., Giraldo, J.P.^‡, Landry, M.P.^‡Nanoparticle-Mediated Genetic Engineering of Plants. Molecular Plant (2019) 12; pp. 1037-1040 – PDF

35. Jeong, S., Yang, D., Beyene, A.G., Gest, A., Landry, M.P.^‡ High Throughput Evolution of Near Infrared Serotonin Nanosensors. Science Advances (2019) 5; DOI: 10.1126/sciadv.aay3771 – PDF

.

2018

34. Del Bonis-O’Donnell, J.T., Pinals, R., Jeong, S., Thakrar, A., Wolfringer, R., Landry, M.P.^‡Chemometric Approaches for Developing Infrared Nanosensors to Image Anthracyclines. ACS Biochemistry (2018). DOI: 10.1021/acs.biochem.8b00926 – PDF

33. Beyene, A.G.*, Delevich, K.*, Yang, S.J., Landry, M.P.^‡New Optical Probes Bring Dopamine to Light. ACS Biochemistry (2018). DOI: 10.1021/acs.biochem.8b00883 – PDF

32. Beyene, A.G., Alizadehmojarad, A.A., Dorlhiac, G., Goh, N., Streets, A.M., Kral, P., Vukovic, L.^‡, Landry, M.P.^‡Ultralarge Modulation of Fluorescence by Neuromodulators in Carbon Nanotubes Functionalized with Self-assembled Oligonucleotide Rings. Nano Letters (2018). DOI: 10.1021/acs.nanolett.8b02937 – PDF

31. Del Bonis-O’Donnell, J.T., Chio, L., Dorlhiac, G.F., McFarlane, I.R., Landry, M.P.^‡Advances in Nanomaterials for Brain Microscopy. NanoResearch (2018). DOI: doi.org/10.1007/s12274‐018‐2145‐2 – PDF

30. Cunningham, F.J.*, Goh, N.*, Demirer, G.S., Matos, J., Landry, M.P.^‡ Nanoparticle-Mediated Delivery Towards Advancing Plant Genetic Engineering. Cell Press Trends in Biotechnology (2018). DOI: 10.1101/179549 – PDF

29. Zou, R., Zhu, X., Tu, Y.^‡, Wu, J.^‡, Landry, M.P.^‡ Activity of Antimicrobial Peptides Decreases with Increased Cell Membrane Crossing Free Energy Cost. ACS Biochemistry (2018). DOI: 10.1021/acs.biochem.8b00052 – PDF

.

2017

28. Kwak, S.Y., Giraldo, J.P., Wong, M.H., Koman, V., Lew, T., Ell, J., Weidman, M., Sinclair, R., Landry, M.P., Tisdale, W.A., Strano, M.S.^‡ A Nanobionic Light Emitting Plant. Nano Letters (2017). DOI: 10.1021/acs.nanolett.7b04369 – PDF

27. Li, S., Zou, R., Tu, Y., Wu, J.^‡, Landry, M.P.^‡ Cholesterol-Directed Nanoparticle Assemblies Based on Single Amino Acid Peptide Mutations Activate Cellular Uptake and Decrease Tumor Volume. RSC Chemical Science (2017). DOI: 10.1039/C7SC02616A – PDF

26. Luo, S., Zou, R., Wu, J.^‡, Landry, M.P.^‡ A probe for the Detection of Hypoxic Cancer Cells. ACS Sensors (2017). DOI: 10.1021/acssensors.7b00171 – PDF

25. Del Bonis-O’Donnell, J.T., Page, R.H., Beyene, A.G., Tindall, E.G., McFarlane, I.R., Landry, M.P.^‡Dual Near-Infrared Two-Photon Microscopy for Deep-Tissue Dopamine Nanosensor Imaging. Advanced Functional Materials (2017). DOI: 10.1002/adfm.201702112 – PDF

24. Beyene, A.G., McFarlane, I.R., Pinals, R.L., Landry, M.P.^‡ Stochastic Simulation of Dopamine Neuromodulation for Implementation of Flurescent Neurochemical Probes in the Striatal Extracellular Space. ACS Chemical Neuroscience (2017). DOI: 10.1021/acschemneuro.7b00193 – PDF

23. Demirer, G.S., Landry, M.P.^‡ Delivering Genes to Plants. AIChE SBE (2017). – PDF

22. Saleh, N. B., Das, D., Plazas-Tuttle, J., Yang, D., Del Bonis-O’Donnell, J.T., Landry, M.P.^‡ Importance and challenges of environmental ligand binding and exchange: Introducing single molecule imaging as a model characterization technique. NanoImpact (2017). DOI: 10.1016/j.impact.2017.03.005. – PDF

21. Chio, L.*, Yang, D.*, Landry, M.P.^‡ Surface Engineering of Nanoparticles to Create Synthetic Antibodies. Methods in Molecular Biology (2017). 1575 363-380 – PDF

20. Landry, M.P., Ando, H., Chen, A.Y., Cao, J., Kottadiel, V.I., Chio, L., Yang, D., Dong, J., Lu, T.K., Strano, M.S.^‡ Single-molecule detection of protein efflux from microorganisms using fluorescent single-walled carbon nanotube sensor arrays. Nature Nanotechnology (2017), DOI: 10.1038/NNANO.2016.284 – PDF

19. Del Bonis-O’Donnell, Jackson T., Beyene, A. G., Chio, L., Demirer, G. S., Yang, D., Landry, M.P.^‡ Engineering Molecular Recognition with Bio-mimetic Polymers On Single Walled Carbon Nanotubes. JOVE (2017). 119 e55030, doi:10.3791/55030

18. Beyene, A. G., Demirer, G. S., Landry, M.P.^‡ Nanoparticle-Templated Molecular Recognition Platforms for Detection of Biological Analytes. Current Protocols in Chemical Biology (2016). 8 (3) 197 – 223 – PDF

.

Patents

Landry M. P.^‡, Grandio, E., Jeong, S. High-Yielding Extraction of Single-Stranded Nucleotides with Solid Substrates. Invention disclosure BK-2021-079 filed December 2020

Landry M. P.^‡, Pinals, R.L. SARS-CoV-2 Detection by Carbon Nanotube-Based Nanosensors. Invention disclosure B21-048 filed October 2020

Landry M. P.^‡, Zhang, H., Demirer, G.D. Gene Silencing in Plants with DNA Origami Nanostructures. Invention disclosure BK-2019-044 filed September 2018

Landry M. P.^‡, Demirer, G.D. Mature plant transformation with nanoparticle-grafted gene vectors. International patent application 62/500,450 filed via UC Berkeley, March 2017

Landry M. P.^‡, Wilbrecht, L., Beyene, A. B., O’Donnell J.T.D. Near-Infrared probes for modulatory neurotransmitter imaging in brain tissue. U.S. Provisional patent application 16/373,542 filed via UC Berkeley, September 2016

~~—————————~~ Prior Publications & Patents ~~———– —————~~

2016

17. Bisker, G., Dong, J., Park, H.D., Iverson, N.M., Ahn, J., Nelson, J.T., Landry, M.P., Kruss, S., Strano, M.^‡ Protein-targeted corona phase molecular recognition. Nature Communications (2016) 7, 1-14 – PDF

16. Wong, M.H., Misra, R., Giraldo, J.P., Kwak, S.Y., Son, Y., Landry, M.P., Swan, J., Blankschtein, D., Strano, M.S.^‡ Lipid Exchange Envelope Penetration (LEEP) of Nanoparticles for Plant Engineering: A Universal Localization Mechanism. Nano Letters (2016). DOI: 10.1021/acs.nanolett.5b04467 – PDF

15. Salem, D.P., Landry, M.P., Bisker, G., Kruss,S., Strano,M.S.^‡ Chirality-Dependent Corona Phase Molecular Recognition of DNA-Wrapped Carbon Nanotubes. Carbon (2016). 97, 147-153 – PDF

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2015

14. Jain, R. M., Ben-Naim, M., Landry, M.P., Strano, M.S.^‡ Competitive Binding in Mixed Surfactant Systems for Single Walled Carbon Nanotube Separation. Journal of Physical Chemistry (2015). 119, 22737-22745 – PDF

13. Olivera, S., Bisker, G., Bakh, N., Gibbs, S., Landry, M.P., Strano M.S.^‡ Protein-Conjugated Carbon Nanomaterials for Biomedical Applications. Carbon (2015). 95, 767-779 – PDF

12. Nelson, J.T., Reuel, N.F., Salem, D.P., Bisker, G., Kruss, S., Kim, S., Landry, M.P., and Strano, M.S.^‡ The Mechanism of Immobilized Protein A Binding to IgG to Nanosensor Array Surfaces. Analytical Chemistry (2015). 87, 8186-8193 – PDF

11. Giraldo, J.P.*, Landry, M.P.*, Kwak, S.Y., Jain, R.M., Wong, M.H., Iverson, N.M., Ben-Naim, M., Strano,M.S.^‡ A Ratiometric Sensor Using Single Chirality Near-Infrared Fluorescent Carbon Nanotubes: Applications to In Vivo Monitoring. Small (2015). 11, 3973-3984 – PDF

10. Landry, M.P., Vukovik, L., Kruss, S., Bisker, G., Landry, A.M., Schulten, K., Strano,M.S.^‡ Comparative Dynamics and Sequence Dependence of DNA and RNA Binding to Single Walled Carbon Nanotubes. Journal of Physical Chemistry (2015). 119 (18) 10048 – 10058 – PDF

.

2014

9. Paulus, G. L., Nelson, J.T., Lee, K., Wang, Q., Reuel, N., Grassbaugh, B., Kruss, S., Landry, M.P., Kang, J.W., Vander Ende, E., Zhang, J., Mu, B., Dasari, R., Opel, C., Wittrup, D.K., Strano, M.S.^‡ A graphene-based physiometer array for the analysis of single biological cells. Scientific Reports (2014). 4 (6865)1–11 – PDF

8. Landry, M.P., Kruss, S., Nelson, J.T., Bisker, G., Iversion, N.M., Reuel, N.F., Strano, M.S.^‡ (Invited Submission). Experimental Approaches to Study the Structure and Dynamics of the Corona Phase of Nanosensors for Synthetic Molecular Recognition. Sensors (2014). 14 (9) 16196 – 16211 – PDF

7. Giraldo, J.P., Landry, M.P., Faltermeier, S. M., McNicholas, T.P., Boghossian, A. A., Reuel, N.F., Hilmer, A. J., Sen, F., Brew, J. A., Strano, M.S.^‡ Plant Nanobionics Approach to Augment Photosynthesis and Biochemical Sensing. Nature Materials (2014). 13, 400 – 408 – PDF

Highlighted in Nature Nanotechnology News (2014), G. Scholes, E. Sargent 13, 329 – 331

6. Kruss, S.*, Landry, M.P.*, Vander Ende, E., Lima, B. M., Reuel, N.F., Zhang, J., Nelson, J., Mu, B., Hilmer, A., Strano,M.S.^‡ Selective photoluminescence increase of nuleic acid wrapped SWNTs by catecholamines. JACS (2014), 136 (2), 713-24 – PDF

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≤ 2013

5. Zhang, J.*, Landry, M.P.*, Barone, P. W.*, Kim, J.*, Strano, M.S.^‡ et al. (2013). Molecular Recognition Using Nanotube-Adsorbed Polymer Complexes. Nature Nanotechnology (2013), 8, 959 – 968 – PDF

Highlighted in Nature Nanotechnology News (2013), Davide Bonifazi 8, 896 – 897

4. Wang, Q.; Bellisario, D.; Drahushuk, L.; Jain, R.; Kruss, S.; Landry, M.P.; Mahajan, S.; Shimizu, S.; Ulissi, Z.; Strano, M.S.^‡ (Invited Submission). Low Dimensional Carbon Materials for Applications in Mass and Energy Transport. ACS Chemistry of Materials (2013). A-L – PDF

3. Landry, M.P., Zou, X., Wang, L., Huang, W.M., Schulten, K. Chemla, Y. R.^‡ Protein-DNA Target Search Mechanisms for Higher-Order Protein Complexes. Nucleic Acids Research (2012). 40, 1-12 – PDF

2. Landry, M.P.^‡ The Pursuit of Science in a Globalized Market: An Approach to Internationally Collaborative Science in Chemistry as a Second Language: Chemical Education in a Globalized Society (Flener, C, ed). American Chemical Society (2010). Ch. 4 pp. 67-89

1. Landry, M.P., McCall, P.M., Qi, Z., Chemla, Y.R.^‡ Characterization of photoactivated singlet oxygen damage in single-molecule optical trap experiments. Biophysical Journal (2009). 97, 2128-36 – PDF

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Patents

Giraldo, J.P., Strano M.S.^‡, Landry M.P. Ratiometric and multiplexing sensors from single chirality single walled carbon nanotubes. U.S. Patent 62/052,767, filed 09/19/2014

Giraldo J.P., Strano, M.S.^‡, Landry, M.P., Faltermeier S.M. Nanobionic Engineering of organelles and photosynthetic organisms. U.S. Patent 61/909,520 filed November 13, 2013. International patent PCT/US2014/050127 filed 8/7/2014 – PDF